Sole system for an article of footwear incorporating a knitted component with a one-piece knit outsole and a tensile element

ABSTRACT

An article of footwear including a sole system, including an upper and the sole system. The sole system includes a knitted component incorporating a one-piece knit outsole. The knit outsole has a ground-facing side, a top side, an inlaid tensile element, and a ground-engaging cleat member protruding from the ground-facing side of the knit outsole. The tensile element may be adjacent a cleat member. The upper is connected at its bottom to the top side of the knit outsole.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/800,158, filed Feb. 25, 2020, which is a continuation of U.S. patentapplication Ser. No. 14/598,433, filed Jan. 16, 2015, which are herebyincorporated by reference in their entireties.

BACKGROUND

The present disclosure relates generally to a sole system for an articleof footwear incorporating a knitted component with a one-piece knitoutsole and a tensile element. The present disclosure also relates to anarticle of footwear comprising the knitted component. The presentdisclosure further is related generally to a method of knitting theknitted component, and to a method of making an article of footwearcomprising the knitted component.

Conventional articles of footwear generally include two primaryelements, an upper and a sole structure. The upper is secured to thesole structure and forms a void on the interior of the footwear forcomfortably and securely receiving a foot. The sole structure is securedto a lower area of the upper, thereby being positioned between the upperand the ground. In athletic footwear, for example, the sole structuremay include a midsole and an outsole. The midsole often includes apolymer foam material that attenuates ground reaction forces to lessenstresses upon the foot and leg during walking, running, and otherambulatory activities. Additionally, the midsole may includefluid-filled chambers, plates, moderators, or other elements thatfurther attenuate forces, enhance stability, or influence the motions ofthe foot. The outsole is secured to a lower surface of the midsole andprovides a ground-engaging portion of the sole system formed from adurable and wear-resistant material, such as rubber. The sole system mayalso include a sockliner positioned within the void and proximal a lowersurface of the foot to enhance footwear comfort.

The upper generally extends over the instep and toe areas of the foot,along the medial and lateral sides of the foot, under the foot, andaround the heel area of the foot. In some articles of footwear, such asbasketball footwear and boots, the upper may extend upward and aroundthe ankle to provide support or protection for the ankle. Access to thevoid on the interior of the upper is generally provided by an ankleopening in a heel region of the footwear. A lacing system is oftenincorporated into the upper to adjust the fit of the upper, therebypermitting entry and removal of the foot from the void within the upper.The lacing system also permits the wearer to modify certain dimensionsof the upper, particularly girth, to accommodate feet with varyingdimensions. In addition, the upper may include a tongue that extendsunder the lacing system to enhance adjustability of the footwear, andthe upper may incorporate a heel counter to limit movement of the heel.

Articles of footwear often are constructed of many components. Forexample, an article of footwear may include many components, such as anupper, a sockliner, a strobel, a midsole, and an outsole. An outsole mayhave spikes, cleats, or other protrusions to provide additional tractionunder selected circumstances. Each of these components is attached to atleast one, typically two, and maybe three or more of the othercomponents. Some components thus are stitched to, adhered to, orotherwise attached to other components.

Construction of an article of footwear comprising many components mayrequire that components having significantly different properties andcharacteristics must be attached to each other. For example, an uppermay be formed from cloth, a midsole from soft foam, and an outsole fromwear-resistant rubber. These components often can be adhered withadhesives. Adhesive may fail, causing delamination of the components.Further, wear may occur at joints between harder and softer materials,or between dissimilar materials. Therefore, such joints may causepremature failure of the article of footwear. Such joints also mayprovide uncomfortable sudden transitions between areas of softer or morecompliant materials and areas of harder or more rigid materials.

Further, assembly of multiple components may be time-consuming and maylead to errors. For example, components from one style of an article offootwear may incorrectly be used on a different style of footwear. Thenumber of potential errors and premature failures may be significant.

A variety of material elements (e.g., textiles, polymer foam, polymersheets, leather, synthetic leather) are conventionally utilized inmanufacturing an article of footwear. In athletic footwear, for example,the upper may have multiple layers that each include a variety of joinedmaterial elements. As examples, the material elements may be selected toimpart stretch-resistance, wear-resistance, flexibility,air-permeability, compressibility, comfort, and moisture-wicking todifferent areas of the upper. Similarly, the sole structure may utilizea number of components to provide selected properties andcharacteristics. To impart the different properties to different areasof the article of footwear, material elements are often cut to desiredshapes and then joined together, usually with stitching or adhesivebonding. Moreover, the material elements often are joined in a layeredconfiguration to impart multiple properties to the same areas. As thenumber and type of material elements incorporated into the article offootwear increases, the time and expense associated with transporting,stocking, cutting, and joining the material elements also may increase.Waste material from cutting and stitching processes also accumulates toa greater degree as the number and type of material elementsincorporated into the article of footwear increases. Moreover, articlesof footwear with a greater number of material elements may be moredifficult to recycle than articles of footwear formed from fewer typesand numbers of material elements. By decreasing the number of materialelements utilized in the article of footwear, therefore, waste may bedecreased while increasing the manufacturing efficiency andrecyclability of the upper.

Reducing the number of material elements may require that one materialelement provide multiple and additional properties and characteristicssought by users. Thus, there exists a need in the art for articles offootwear comprising a minimum number of material elements whileproviding a number of properties and characteristics sought by users.

SUMMARY

Various configurations of an article of footwear may have an upper and asole system associated with the upper. Both the upper and the solesystem may incorporate a knitted component.

In one aspect, the disclosure provides a sole system for an article offootwear. The sole system includes a knitted component incorporating aone-piece knit outsole and a tensile element. The knit outsole has aground-facing side and a top side. A protruding ground-engaging cleatmember is formed on the ground-facing side of the knit outsole. Thetensile element may be manipulated from the ground-facing side.

In another aspect, the disclosure provides an article of footwearincluding the sole system. The article of footwear includes an upper andthe sole system connected thereto. The upper may be one-piece or mayhave a strobel sock or other closure at the bottom of the upper. The topside of the outsole and the bottom of the upper are affixed.

The disclosure also provides an aspect including a method of making asole system for an article of footwear. In accordance with the method, aground-engaging member is formed in a one-piece knit outsole having aground-facing side, a top side, and a tensile element. A protrudingground-engaging cleat member is formed by molding the knitted component.

In another aspect, the disclosure provides a method of making a solesystem for an article of footwear. In accordance with the method, aone-piece knitted component is knitted to include a knit outsole havinga tensile element. A ground-engaging cleat member is formed in theground-facing side of the knit outsole by knitting.

In still another aspect, the disclosure provides a foot-enclosing solesystem for an article of footwear. The sole system includes a one-piecefoot-enclosing knit portion that encloses the foot and includes a knitoutsole. The knit outsole has a ground-facing side, a top side, and atensile element. A ground-engaging cleat member protrudes from theground-facing side of the outsole.

Other systems, methods, features, and advantages of the invention willbe, or will become, apparent to one of ordinary skill in the art uponexamination of the following figures and detailed description. It isintended that all such additional systems, methods, features andadvantages be included within this description and this summary, bewithin the scope of the invention, and be protected by the followingclaims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention can be better understood with reference to the followingdrawings and description. The components in the figures are notnecessarily to scale, emphasis instead being placed upon illustratingthe principles of the invention. Moreover, in the figures, likereference numerals designate corresponding parts throughout thedifferent views.

FIG. 1 is a perspective view of an exemplary embodiment of an article offootwear;

FIG. 2 is a lateral side elevational view of the exemplary embodiment ofan article of footwear;

FIG. 3 is a medial side elevational view of the exemplary embodiment ofan article of footwear;

FIG. 4 is a bottom view of an exemplary embodiment of an article offootwear;

FIG. 5 is a bottom view of an exemplary embodiment of an article offootwear before a foot-enclosing portion is formed;

FIG. 6 is a perspective view of the bottom of an exemplary embodiment ofthe article of footwear of FIG. 5 as the foot-enclosing portion isformed;

FIG. 7 is a perspective view of an exemplary embodiment of the completedarticle of footwear of FIG. 5 and FIG. 6 ;

FIG. 8 is a schematic diagram of an exemplary embodiment of a method ofmaking an article of footwear;

FIG. 9 is a perspective view of a knitting process using conventionalfeeders and a combination feeder;

FIG. 10 is a perspective view of a portion of a knitting process usingconventional feeders and a combination feeder;

FIG. 11 is a perspective view of a portion of a knitting process usingconventional feeders and a combination feeder;

FIG. 12 is a perspective view of an exemplary embodiment of a knittedcomponent;

FIG. 13 is a view of a section of a knitted component including atensile element;

FIG. 14 is a view of the section of a knitted component illustrated inFIG. 13 , wherein a tensile element is pulled to create more tension inthe tensile element;

FIG. 15 is a view of a section of a knitted component wherein a tensileelement is pulled toward another tensile element to create tension;

FIG. 16 is a view of a section of FIG. 15 wherein the other tensileelement is pulled to form a loop that is secured under another tensileelement;

FIG. 17 is a view of a mold and a knitted component to be molded to formcleat members;

FIG. 18 is a view of a mold and a knitted component to be molded byinjecting material to form cleat members;

FIG. 19 is a view of a mold closed on a knitted component to form cleatmembers;

FIG. 20 is a perspective view of a molded knitted component removed fromthe mold;

FIG. 21 is a comparison of tensile elements that apply force indifferent directions, including a close-up of relevant knit patterns;

FIG. 22 is a perspective view of a bottom of a knitted component;

FIG. 23 is a perspective view of an outsole having cleat members;

FIG. 24 illustrates a relationship between the outsole of FIG. 17 and anupper; and

FIG. 25 illustrates an assembled article of footwear with the upperattached to the outsole.

DETAILED DESCRIPTION

An article of footwear 100 is depicted in FIGS. 1-4 as including a solesystem 110 and an upper 120. Although footwear 100 is illustrated ashaving a general configuration suitable for enhanced traction, conceptsassociated with footwear 100 may also be applied to a variety of otherenhanced traction-type athletic footwear types, including baseballshoes, cycling shoes, football shoes, soccer shoes, and hiking boots,for example. The concepts may also be applied to footwear types that aregenerally considered to be non-athletic, including work boots.Accordingly, the concepts disclosed with respect to footwear 100 applyto a wide variety of footwear types.

The following discussion and accompanying Figures disclose a variety ofconcepts relating to knitted components and the manufacture of knittedcomponents. Although the knitted components may be utilized in a varietyof products, an article of footwear that incorporates one of the knittedcomponents is disclosed below as an example. The description will bedirected in detail to an article of footwear. However, in addition tofootwear, the knitted components may be utilized in other types ofapparel (e.g., gloves or mittens) where the ability to securely grip anobject may be enhanced by protuberances. Accordingly, the knittedcomponents and other concepts disclosed herein may be incorporated intoa variety of products for both personal and industrial purposes.

For reference purposes, footwear 100 may be divided into three generalregions: a forefoot region 101, a midfoot region 102, and a heel region103. Forefoot region 101 generally includes portions of footwear 100corresponding with the toes and the joints connecting the metatarsalswith the phalanges. Midfoot region 102 generally includes portions offootwear 100 corresponding with an arch area of the foot. Heel region103 generally corresponds with rear portions of the foot, including thecalcaneus bone. Footwear 100 also includes a lateral side 104 and amedial side 105, which extend through each of forefoot region 101,midfoot region 102, and heel region 103 and correspond with oppositesides of footwear 100. More particularly, lateral side 104 correspondswith an outside area of the foot (i.e., the surface that faces away fromthe other foot), and medial side 105 corresponds with an inside area ofthe foot (i.e., the surface that faces toward the other foot). Forefootregion 101, midfoot region 102, heel region 103, lateral side 104, andmedial side 105 are not intended to demarcate precise areas of footwear100. Rather, forefoot region 101, midfoot region 102, heel region 103,lateral side 104, and medial side 105 are intended to represent generalareas of footwear 100 to aid in the following discussion. In addition tofootwear 100, forefoot region 101, midfoot region 102, heel region 103,lateral side 104, and medial side 105 may also be applied to sole system110, upper 120, and individual elements thereof.

Embodiments of the disclosure provide a sole system for an article offootwear. The sole system includes a knitted component incorporating aone-piece knit outsole having a tensile element. The knit outsole has aground-facing side, a top side, and a tensile element. A protrudingground-engaging cleat member is formed on the ground-facing side of theknit outsole. The ground-engaging cleat member has a surface comprisinga knitted textile that engages the ground.

Sole system 110 is secured to upper 120 and extends between the foot andthe ground when footwear 100 is worn. The primary elements of solesystem 110 are a knitted component 111, a one-piece knit outsole 112, anoutsole top surface or side 113 (see FIG. 20 ), an outsole bottomsurface or side 114, and a ground-engaging cleat member 115, firsttensile element 161, second tensile element 162, third tensile element163, and fourth tensile element 164. Any number of tensile elements maybe included. Knitted component 111 forming one-piece knit outsole 112 issecured to a lower surface of upper 120 and may be formed from aone-piece knitted component. One-piece knit outsole 112 is secured toupper 120 and may be formed from knitted component 111. Outsole topsurface or side 113 is located on the top surface of one-piece knitoutsole 112, and is positioned to extend under a lower surface of thefoot. Outsole bottom surface or side 114 comprises the outer bottomground-facing surface of sole system 110 and the bottom surface ofarticle of footwear 100. This side of the sole faces away from the foot,and may be ground-engaging if, for example, ground-engaging cleat member115 becomes embedded in the ground. Ground-engaging cleat members 115protrude from outsole bottom surface 114. First tensile element 161,second tensile element 163, third tensile element 163, and fourthtensile element 164 are inlaid within bottom surface 116. Bottom 116 ofground-engaging cleat member 115 engages the ground first. Although thisconfiguration for sole system 110 provides an example of a sole systemthat may be used in connection with upper 120, a variety of otherconventional or nonconventional configurations for sole system 110 mayalso be utilized. Accordingly, the features of sole system 110 or anysole system utilized with upper 120 may vary considerably.

Additional embodiments provide a foot-enclosing sole system for anarticle of footwear. The sole system includes a one-piece foot-enclosingknit portion that encloses the foot and includes a knit outsole having atensile element. The sole system thus includes both an outsole and anupper. The outsole and the upper may be knit together as a one pieceelement. The knit outsole has a ground-facing side, a top side, and atensile element. A ground-engaging cleat member protrudes from theground-facing side of the outsole. A tensile element is inlaid withinthe knitted component on the ground-facing side of the outsole. Theground-engaging cleat member may include a knit surface that contactsthe ground.

Upper 120 defines a void within footwear 100 for receiving and securinga foot relative to sole system 110. The void is shaped to accommodatethe foot and extends along a lateral side of the foot, along a medialside of the foot, over the foot, around the heel, and under the foot.Access to the void is provided by an ankle opening 121 located in atleast heel region 103. In further configurations, upper 120 may includeadditional elements, such as (a) a heel counter in heel region 103 thatenhances stability, (b) a toe guard in forefoot region 101 that isformed of a wear-resistant material, (c) a collar extending around ankleopening 121, and (d) logos, trademarks, and placards with careinstructions and material information.

Many conventional footwear uppers are formed from multiple materialelements (e.g., textiles, polymer foam, polymer sheets, leather, andsynthetic leather) that are joined through stitching or bonding, forexample. In contrast, in embodiments of the disclosure, a majority ofupper 120 may be formed from a knitted component 130, which extendsthrough each of forefoot region 101, midfoot region 102, and heel region103 along both lateral side 104 and medial side 105, over forefootregion 101, and around heel region 103. In addition, knitted component130 forms portions of both an exterior surface and an opposite interiorsurface of upper 120. As such, knitted component 130 defines at least aportion of the void within upper 120. In some configurations, knittedcomponent 130 may also extend under the foot.

Thus, in one aspect, the disclosure provides a method of making a solesystem for an article of footwear. In accordance with the method, aone-piece knitted component is knitted to include a knit outsole. Aground-engaging cleat member is formed in the ground-facing side of theknit outsole by knitting. A protruding ground-engaging cleat member maybe formed by molding the knitted component. The cleat member may have aground-engaging surface comprising a knitted surface that engages theground and may provide traction. At least one tensile element may beadjacent the cleat member.

Embodiments including a foot-enclosing sole system provide an article offootwear that may be formed from a one-piece knitted component. Thus,the upper and the outsole may comprise a knitted textile formed togetheras a one-piece element. Forming an article of footwear as a one piecetextile element through knitting provides significant advantages overtypical articles of footwear. For example, there is no need to attach anoutsole to an upper, thus significantly reducing the number of stepsrequired for assembly and, therefore, the possibility of assemblyerrors. Also, there are no joints at which disparate properties andcharacteristics of the joined materials may cause excessive wear andpremature failure.

In some embodiments, knitted component 130 and sole system 110 comprisea single knitted component. FIG. 1 through FIG. 4 illustrate such anembodiment, wherein knitted component 130 and sole system 110 comprise asingle knitted component including a tensile element. In theseembodiments, knitted component 130 and knitted component 111 of solesystem 110 are formed of unitary knit construction so as to be aone-piece element. Joint 117 depicts a joint between upper 120 and solesystem 110. However, for embodiments including sole system 110 having aone-piece foot-enclosing knit portion that encloses the foot andincludes a knit outsole, joint 117 is not present. Rather, joint 117 isillustrated as a line of demarcation between sole system 110 and upper120. No indicia corresponding to joint 117 may actually be physicallypresent or visible on article 100.

In various embodiments, knitted component 130 may incorporate varioustypes of yarn that impart different properties to separate areas ofupper 120. For example, one area or portion of knitted component 130 maybe formed from a first type of yarn that imparts a first set ofproperties, and another area or portion of first knitted component 130may be formed from a second type of yarn that imparts a second set ofproperties. In this configuration, properties may vary throughout upper120 by selecting specific yarns for different areas of knitted component130. Similarly, knitted component 111 of sole system 110 may be knittedfrom various yarns, including any of the yarns used to form knittedcomponent 130.

Yarns used in embodiments of the disclosure may be selected frommonofilament yarns and multifilament yarns formed from natural orsynthetic materials. Multifilament yarns may be twisted or untwisted. Insome embodiments, yarn may be elastic or essentially inelastic. In someembodiments, yarn may be textured or have a natural finish. Naturalmaterials may be selected from staple materials, such as silk, cotton,and wool. Synthetic materials may be selected from polymers that can beformed into filaments. Synthetic materials include but are not limitedto polyesters; polyamides, such as any of the various types ofhomopolymeric and co-polymeric nylon; aramides, such as Kevlar® andNomex®; and urethanes, such as thermoplastic polyurethane. Fusible yarnsalso may be suitable for embodiments.

In embodiments of the disclosure, the yarn used to form the article offootwear may incorporate yarns with different deniers, materials (e.g.,cotton, elastane, polyester, rayon, wool, and nylon), and degrees oftwist, for example. The different types of yarns may affect the physicalproperties of a knitted component, including aesthetics, stretch,thickness, air permeability, and abrasion-resistance. In someconfigurations, multiple yarns with different colors may be utilized toform the knitted component. When yarns with different colors are twistedtogether and then knitted, the knitted component may have a heatheredappearance with multiple colors randomly distributed throughout.

In some embodiments, any number of tensile elements or tensile strandsmay be inlaid or placed along any suitable area of outsole bottomsurface 114. Moreover, tensile elements suitable for use with outsolebottom surface 114 may include the tensile strands or tensile elementsand the method of manufacturing a knitted component incorporatingtensile elements disclosed in one or more of the commonly-owned U.S.application Ser. No. 13/048,540 to Huffa et al., entitled “Method OfManufacturing A Knitted Component”, filed on Mar. 15, 2011 and publishedas United States Patent Application Publication No. 2012/0234052 on Sep.20, 2012; U.S. Pat. No. 8,490,229 to Dua et al., entitled “Article ofFootwear Having An Upper Incorporating a Knitted Component”, issued Jul.23, 2013; and U.S. Pat. No. 8,839,532, entitled “Article Of FootwearIncorporating A Knitted Component”, issued Sep. 23, 2014; the entiretiesof which are hereby incorporated by reference herein.

Other embodiments provide an article of footwear including the solesystem. The article of footwear includes an upper and the sole systemconnected thereto. The upper may be one-piece or may have a strobel sockor other closure at the bottom of the upper. The top side of the outsoleand the bottom of the upper are affixed. The surface of theground-engaging cleat member on the sole system comprises a knittedtextile, and the textile engages the ground. A tensile element also maybe present.

In some embodiments, sole system 110 and knitted component 130 may beformed of unitary knit construction such that they may be knitted as aone-piece element to form a foot-enclosing knit portion 140. FIG. 5illustrates such an embodiment. FIG. 5 illustrates an essentially planaror flat foot-enclosing knit portion 140 comprising sole system 110 andknitted component 130. Knitted component 130 is illustrated in twoelements on opposite sides of sole system 110. Sole system 110 includesknitted component 111 forming one-piece knit outsole 112 having bottomsurface 114, and ground-engaging cleat member 115 having bottom 116.First tensile element 161, second tensile element 162, third tensileelement 163, and fourth tensile element 164 may be inlaid within knittedcomponent 111. In some embodiments, one or more of tensile element 161,tensile element 162, tensile element 163, or tensile element 164 may beexposed on bottom surface 114. Line of demarcation 117 is illustratedfor purposes of reference.

FIG. 5 , FIG. 6 , and FIG. 7 illustrate an exemplary process of formingarticle of footwear 100 from foot-enclosing knit portion 140, which isflat or planar in FIG. 5 , and is configured into a completed article offootwear 100 in FIG. 7 . FIG. 6 illustrates an intermediate stage,wherein foot-enclosing knit portion 140 has been folded or bent upwardfrom about line of demarcation 117, clearly distinguishing sole system110 from knitted component 130. Knitted component 111, one-piece knitoutsole 112 having bottom surface 114, ground-engaging cleat member 115having bottom 116, and first tensile element 161, second tensile element162, third tensile element 163, and fourth tensile element 164, areclearly visible as part of sole system 110. In FIG. 6 , the forefootarea is completely formed, but the heel edges of knitted component 130have not been brought together.

FIG. 7 illustrates a complete article of footwear 100 fromfoot-enclosing knit portion 140. Article of footwear 100 comprisesknitted component 130 and sole system 110. Upper 120 is formed bystitching or otherwise attaching the ends of knitted component 130 atseam 127 in the forefoot region and the midfoot region and at seam 129in the heel region to form a void for a wearer's foot.

In some embodiments, seam 127 and seam 129 resulting from the stitchingor joining together of the sides of knitted component 130 may be locatedessentially on the longitudinal midline of article of footwear 100 ifthe size of knitted component 130 is essentially the same on each sideof article of footwear 100, as illustrated in the drawing Figuresherein. In other embodiments of the disclosure, the seam may be locatedanywhere on the surface of upper 120. Such an adjustment can be made bymaking one side of knitted component 130 wider than the other.

Line of demarcation 117 illustrates a dividing line between sole system110 and other components of the article of footwear 100. Ground-engagingcleat member 115 protrudes away from the bottom side or surface 114 ofone-piece knit outsole 112. First tensile element 161, second tensileelement 162, third tensile element 163, and fourth tensile element 164may be inlaid within knitted component 111. In some embodiments, one ormore of tensile element 161, tensile element 162, tensile element 163,or tensile element 164 may be exposed on bottom surface 114.

In the embodiments illustrated in FIG. 1 through FIG. 7 , the tensileelements may be located adjacent ground-engaging cleat members 115.Location of the tensile elements in this way may control stretching ofthe sole during use. For example, location of the tensile elementslongitudinally may control lengthwise stretch of outsole 112. Further,locating a tensile element adjacent a ground-engaging cleat member maycontrol stretch at the periphery of the base of the ground-engagingcleat member. Such stretch may be introduced by wear or as part of themanufacturing process, particularly the process by which theprotuberance for the cleat member is formed in the knitted component.Extending the tensile element along a side of a plurality of cleatmembers also helps control stretching between cleats.

FIG. 8 is a block schematic diagram of a method 500 for manufacturing anarticle of footwear in accord with the disclosure. In accordance withthe method of knitting a textile element (such as knitted component 111and/or knitted component 130) is begun in step 520. As part of thisknitting, a tensile element, such as tensile element 161, may be inlaidwithin the textile element in step 525. Knitting continues (step 530)until the textile element is complete. The tensile element may beadjusted in step 535. Ground-engaging cleat members are formed in step540. The textile may be steamed to set the yarn, in accordance withknown processes. Then, areas of the textile element may be stiffened atmethod step 560. Typically, such stiffening would be useful in areas ofthe textile element subject to heavy abrasion. Fusible yarn may be usedin this area, for example, on portions of knitted componentscorresponding to protuberances forming ground-engaging cleat members.Fusible yarn may be heated at step 563 to soften the outer surfaces ofthe yarn. Alternatively, a stiffening resin or plastic may be appliedand activated and cured or heated at step 566. Typically, stiffeningresins or plastics are located so as not to interfere with adjustmentsby the tensile element. Then, the final folding, matching, sticking andadhering to form the article of footwear is carried out as step 590 toform an article of footwear.

In one aspect, the disclosure provides a sole system for an article offootwear. The sole system includes a knitted component incorporating aone-piece knit outsole. The knit outsole has a ground-facing side and atop side. A protruding ground-engaging cleat member is formed on theground-facing side of the knit outsole. A tensile element may be inlaidwithin the knitted component so as to be accessible from theground-facing side of the knit outsole.

In another aspect, the disclosure provides an article of footwearincluding the sole system. The article of footwear includes an upper andthe sole system connected thereto. The upper may be one-piece or mayhave a strobel sock or other closure at the bottom of the upper. The topside of the outsole and the bottom of the upper are affixed.

The disclosure also provides an aspect including a method of making asole system for an article of footwear. In accordance with the method, aground-engaging member is formed in a one-piece knit outsole having aground-facing side and a top side. A protruding ground-engaging cleatmember is formed by molding the knitted component. A tensile element maybe inlaid within the ground-facing side of the one-piece knit outsole.

Knitted component 111, knitted component 130, and foot-enclosing knitportion 140 can be formed of unitary knit construction having an inlaidtensile element. As used herein, the term “unitary knit construction”means that the respective component is formed as a one-piece elementthrough a knitting process. In some embodiments, a tensile element isinlaid within the knitted component. That is, the knitting processsubstantially forms the various features and structures of unitary knitconstruction, including inlaying of a tensile element, without the needfor significant additional manufacturing steps or processes. A unitaryknit construction may be used to form a knitted component havingstructures or elements that include one or more courses of yarn or otherknit material that are joined such that the structures or elementsinclude at least one course in common (i.e., sharing a common yarn)and/or include courses that are substantially continuous between each ofthe structures or elements. With this arrangement, a one-piece elementof unitary knit construction is provided. Examples of variousconfigurations of knitted components and methods for forming knittedcomponents with unitary knit construction are disclosed in U.S. Pat. No.6,931,762 to Dua; U.S. Pat. No. 7,347,011 to Dua, et al.; U.S. PatentApplication Publication 2008/0110048 to Dua, et al.; U.S. PatentApplication Publication 2010/0154256 to Dua; and U.S. Patent ApplicationPublication 2012/0233882 to Huffa, et al.; each of which is incorporatedherein by reference in its entirety. Knitted component 111, knittedcomponent 130, foot-enclosing knit portion 140, and tensile element 161remain formed of unitary knit construction when other elements, such aslogos, trademarks, placards with care instructions or other information,such as material information and size, tensile or structural elements,are added following the knitting procedure.

In still another aspect, the disclosure provides a foot-enclosing solesystem for an article of footwear. The sole system includes a one-piecefoot-enclosing knit portion that encloses the foot and includes a knitoutsole. The knit outsole has a ground-facing side and a top side. Atensile element may be located on the ground-facing side. Aground-engaging cleat member protrudes from the ground-facing side ofthe outsole.

Various methods, machines, and tools can be used for forming, treating,and otherwise adjusting knitted component 111 and for forming article offootwear 100 incorporating one-piece knit outsole 112, including tensileelement 161 inlaid therein. It will be appreciated that the order ofsteps within the method may vary from the order described herein.Certain steps or aspects of some steps may be skipped or eliminated aswell. Moreover, two or more steps within the method may be carried outsequentially or simultaneously. Furthermore, the steps within the methodmay be carried out manually or automatically, using any suitable tool,machine, or implement.

FIG. 9 and FIG. 10 illustrate an exemplary process of knitting a knittedcomponent, including a knitted component substantially similar toknitted component 111, knitted component 130, and foot-enclosing knitportion 140 described above. Although knitting may be performed by hand,the commercial manufacture of knitted components is generally performedby knitting machines. An example of a knitting machine 200 that issuitable for producing any of the knitted components described herein isdepicted in FIG. 9 . Knitting machine 200 has a configuration of a V-bedflat knitting machine for purposes of example, but any of the knittedcomponents described herein may be produced on other knitting machines.

Knitting machine 200 includes first needle bed 232 and second needle bed234 having needles 202 that are angled with respect to each other,thereby forming a V-bed. That is, needles 202 from first needle bed 232lay on a first plane, and needles 202 from the second needle bed 234 layon a second plane. The first plane and the second plane are angledrelative to each other and meet to form an intersection that extendsalong a majority of a width of knitting machine 200. As described ingreater detail below, needles 202 each have a first position where theyare retracted and a second position where they are extended. In thefirst position, needles 202 are spaced from the intersection where thefirst plane and the second plane meet. In the second position, however,needles 202 pass through the intersection where the first plane and thesecond plane meet.

Rail 203 and rail 205 extend above and parallel to the intersection ofneedles 202 and provide attachment points for first standard feeder 214.Rail 203 and rail 205 each have two sides, each of which may accommodateone standard feeder. Therefore, knitting machine 200 may include a totalof four feeders. Three such feeders are illustrated in FIG. 9 .Combination feeder 204 is on the front of rail 203, first standardfeeder 214 is on the front of rail 205, and second standard feeder 224is on the back of rail 205. Although two rails are depicted, additionalrails could be present. Such additional rails would accommodateadditional feeders. Such feeders may be useful to manufactureembodiments including two or more types of yarn. These additionalfeeders are supplied with yarn and are operated in the same way as thefeeders described in detail. FIG. 10 and FIG. 11 illustrate a differentarrangement of feeders and rails, wherein combination feeder 204 is onthe front of rail 273 and first standard feeder 214 is on the back ofrail 273. These and other arrangements are available for use with thevarious knitting techniques.

First standard feeder 214 moves along rail 205 and needle beds 232 and234, thereby supplying yarn to needles 202. Yarn 206 is provided tofeeder 204 by a spool 207. More particularly, yarn 206 extends fromspool 207 to various yarn guides 208, yarn take-back spring 209, andyarn tensioner 210 before entering first standard feeder 214. Althoughnot depicted, additional spools 207 may be utilized to provide yarns toother feeders.

Standard feeders are conventionally utilized for a V-bed flat knittingmachine 200. Each standard feeder has the ability to supply yarn thatneedles 202 manipulate to knit, tuck, and float. In some embodiments,only one feeder may be needed. In other embodiments, such as when theground-engaging cleat members are knitted into the one-piece outsole,more than one feeder may be utilized. For such embodiments, a knittingmachine 200 in FIG. 9 may include first standard feeder 214, secondstandard feeder 224, and first combination feeder 204. The standardfeeders are substantially similar to each other; each introduces yarnthat can be manipulated to knit, tuck, and float. The combination feederhas these abilities, and also has the ability to inlay a yarn. Firststandard feeder 214 may be secured to a front side of rail 205, secondstandard feeder 224 may be secured to the back side of rail 205, andfirst combination feeder 204 may be secured to a rear side of rail 203.In other embodiments of the disclosure, additional feeders may be usedand may be located on the front or rear side of rail 203 or rail 205.

In this embodiment, first yarn 206 from spool 207 passes through firststandard feeder 214 and an end of yarn 206 extends outwardly from firstdispensing tip 213 at the end of first feeder arm 212. Although yarn 206is depicted, any other strand (e.g., a filament, thread, rope, webbing,cable, chain, or yarn) may pass through first standard feeder 214. Asecond yarn (not shown) similarly passes through second standard feeder224 and extends outwardly from second dispensing tip 233 on secondfeeder arm 215. A third yarn or tensile element (not shown) may pass ina similar manner through first combination feeder 204 to thirddispensing tip 254 on third feeder arm 227.

Needles 202 are manipulated to form loops 206, with a plurality of loopsforming knitted component 260. The knitting process discussed hereinrelates to the formation of a knitted component 260, which may be anyknitted component, including knitted components that are similar toknitted component 111, knitted component 130, and foot-enclosing knitportion 140, and having an inlaid tensile element 161. For purposes ofthe discussion, only a relatively small section of knitted component 260is shown in the Figures in order to permit the knit structure to beillustrated. Moreover, the scale or proportions of the various elementsof knitting machine 200 and knitted component 260 may be enhanced tobetter illustrate the knitting process.

First standard feeder 214 includes first feeder arm 212 with firstdispensing tip 213, as shown in FIG. 9 , FIG. 10 , and FIG. 11 . Firstfeeder arm 212 is angled to position first dispensing tip 213 in alocation that is (a) centered between needles 202 and (b) above anintersection of needle beds 201. Note that needles 202 lay on differentplanes, which planes are angled relative to each other. That is, needles202 lay on the different planes of first needle bed 232 and secondneedle bed 234. Needles 202 each have a first position in which needles202 are retracted, and a second position, in which needles 202 areextended. In the first position, needles 202 are spaced from theintersection where the planes upon which needle beds 201 meet. In thesecond position, however, needles 202 are extended and pass through theintersection where the planes upon which needle beds 201 meet. That is,needles 202 cross each other when extended to the second position. Itshould be noted that first dispensing tip 213, second dispensing tip223, and third dispensing tip 233, are located above the intersection ofthe planes. In this position, first dispensing tip 213 and seconddispensing tip 254 dispense yarn to needles 202 for purposes ofknitting, tucking, and floating. Third dispensing tip 233 dispenses yarnto needles 202 for the purposes of knitting, tucking, floating, andinlaying.

Referring again to FIG. 10 and FIG. 11 , first standard feeder 214 movesalong rail 273 and a new course is formed in knitted component 260 fromyarn 206. More particularly, needles 202 pull sections of yarn 206through the loops of the prior course, thereby forming the new course.Accordingly, courses may be added to knitted component 260 by movingstandard feeder 204 along needles 202, thereby permitting needles 202 tomanipulate yarn 206 and form additional loops from yarn 206.

FIG. 10 and FIG. 11 further illustrate inlaying of tensile element 161.In FIG. 10 , tensile element 161 extends a short distance from feeder233 in preparation of inlaying tensile element 161 within the previouslyformed course of knitted component 260. FIG. 11 illustrates the resultof translating first combination feeder 204 from left (FIG. 10 ) toright (FIG. 11 ), thereby inlaying tensile element 161 within knittedcomponent 260.

The processes and methods for knitting a knitted component described andillustrated herein are exemplary and are not meant to be exhaustive.Therefore, it should be understood that additional knitted componentsincluding the features of the embodiments described herein, as well assimilar knitted components including the features of the embodimentsdescribed herein, as well as similar knitted components not explicitlydescribed herein, may be made using one or more knitting processessubstantially similar to the knitting method for knitted component sdescribed herein or in the documents incorporated by reference.

Knitted components described herein can be formed from at least one yarnthat is manipulated (e.g., with a knitting machine) to form a pluralityof intermeshed loops that define a knitted component having a variety ofcourses and wales. Thus, adjacent areas of a knitted component can shareat least one common course or at least one common wale. That is, knittedcomponents can have the structure of a knitted textile. It will beappreciated that the knitted components can be formed via weft knittingoperations, including flat knitting operations and circular knittingoperations, warp knitting operations, or other suitable methods.

The knitted components may incorporate various types and combinations ofstitches and yarns. With regard to stitches, the yarn forming theknitted components may have one type of stitch in one area of a knittedcomponent and another type of stitch in another area of the knittedcomponent. Depending upon the types and combinations of stitchesutilized, areas of knitted components may have a plain knit structure, amesh knit structure, or a rib knit structure, for example. The differenttypes of stitches may affect the physical properties of a knittedcomponent, including aesthetics, stretch, thickness, air permeability,and abrasion-resistance. That is, the different types of stitches mayimpart different properties to different areas of the knitted component.With regard to yarns, the knitted component may have one type of yarn inone area of a knitted component 130 and another yarn in a different areaof the knitted component.

Although embodiments of the disclosure have been described in detail asproviding an upper comprising a single layer, the disclosure alsocontemplates uppers having plural layers. The plural layers may befused, double-knit, or otherwise associated with each other.

FIG. 12 illustrates a portion of a knitted component 260, which mayrepresent any of knitted component 111, knitted component 130, orfoot-enclosing knit portion 140. In particular, the portion is thatportion in which ground-engaging cleat member 115 will be formed, so itincludes portions that will become one-piece knit outsole 112, andground-engaging cleat member 115. The portion also includes firsttensile element 161, second tensile element 162, third tensile element163, and tensile element 164. The portion also includes tensile elementloops 166, which represent the travel of the tensile element at the endof the knitted component from one location to another, and tensileelement leads 167, which represent the travel of the tensile element atthe beginning and end of the tensile element. Tensile element loops 166and tensile element leads 167 may permit the inlaid tensile elements tobe adjusted with the knitted component. In some embodiments, tensileelement loops 166 and tensile element leads 167 may be removed from theedges of the textile element when the textile element is formed into aportion of an article of footwear. In some embodiments, tensile elementloops 166 and tensile element leads 167 may be secured or attached tothe bottom of the upper of the article of footwear.

Although the disclosure is described in detail as it relates to aknitted component for a sole system for an article of footwear, theprinciples described herein may be applied to any textile element toprovide a knit surface on a protruding portion of an object to engageanother object. For example, the principles may be applied to studs thatprotrude from the front or back of a glove or mitten to provide a securegrip on an object grasped with the glove or mitten. In such a case, theknitted component on the surface of the protruding object would not beground-engaging, but rather would be object-engaging, and the tensileelements may be located analogously. The tensile element also may belocated along or adjacent to the knuckles, across the palm, at the cuff,or any location amenable of adjustment, as described herein.

The disclosure also is described in detail as it relates to knittedtextiles formed by weft knitting, but textiles formed by any suitableknitting process, including but not limited to: weft knitting processes,for example, flat knitting operations or circular knitting operations;warp knitting process; or any other knitting process suitable forproviding a knitted textile, may be used.

A ground-engaging member may be formed on the knitted component in thesole system. The ground-engaging member protrudes from the ground-facingsurface of the outsole. At least the bottom surface of theground-engaging member engages the ground, and the sides of theground-engaging member also may engage the ground.

In some embodiments, a ground-engaging member may be formed bystretching the knitted component in the area of the outsole where theground-engaging member is to be located to form a protuberance.Typically, protuberances are found in the forefoot and in the heel,although protuberances may be placed anywhere on the outsole surface. Ifplural ground-engaging members are to be formed, they may be formed bystretching the knitted component individually, essentiallysimultaneously, in groups, or simultaneously to form the protuberances.

In some embodiments, a mold may be formed by any suitable method. Themold may have a single protuberance, or may have a protuberance for eachground-engaging member to be formed by the stretching operation. Inother embodiments, two molds may be necessary. One mold may be used toform protuberances extending from the forefoot area, and the second moldmay be used to form protuberances extending from the heel area.

In embodiments, all protuberances are formed essentially simultaneously.A mold may have a male part and a mated female part into which the malepart is pressed. The knitted component is placed in an open mold,typically on the female part of the open mold. The knitted component islocated so that the portion of the knitted component that forms thebottom of the sole is appropriately registered with the portions of thefemale mold that form the protuberances. The mold ensures that theknitted component is retained at the edges so that the protuberances areformed by stretching, rather than by forcing extra textile into thecavity and wrinkling the remainder of the knitted component. Then, themale part of the mold is pressed into the knitted component and into thefemale part of the mold to form the protuberances in the sole. The moldparts then are separated, and the knitted component with protuberancesis advanced for further processing.

The tensile elements may be manipulated to adjust the tension in aportion of a knitted component. The wearer may adjust the tension toprovide a secure fit by adjusting longitudinal (along the length of anarticle of footwear) tension, lateral (across the width of the articleof footwear) tension, or both. Such adjustments also may be made tocompensate for any slackness that develops during wear and use of thearticle of footwear. The tensile elements also may be used to adjusttension in the shoe outsole in the area of cleat members or otherprotuberances.

FIG. 13 through FIG. 16 illustrate exemplary embodiments of adjustingtensile elements to increase longitudinal (FIG. 13 and FIG. 14 ) tensionor both longitudinal and lateral (FIG. 15 and FIG. 16 ) tension. Theseare merely several exemplary embodiments of how the tensile elements canbe used in an article of footwear.

FIG. 13 illustrates equal adjustment of adjacent tensile elements.Knitted component 360 includes tensile element 361 and tensile element362. Portions of the tensile elements are shown. FIG. 13 illustratesequal tension being introduced into adjacent tensile element 361 andtensile element 371 by pulling on them equally, thus forming loop 365 intensile element 361 and loop 375 in tensile element 371. Increasing thesize of the loop increases the tension in the tensile element, and thusin the affected region of knitted component 360.

In some embodiments, the loops can be made by pulling the tensileelement with the fingers or a suitable tool. The loop may be pulled awayfrom the ground-engaging surface, may be pulled parallel to the surfaceof the sole, or may be pulled at any angle.

FIG. 14 illustrates an exemplary process of introducing additionaltension into a single tensile element. As can be seen, loop 465 islarger than loop 475. Therefore, more tension is introduced into tensileelement 461 by loop 465 than is introduced into tensile element 471 byloop 475, as loop 475 is much larger than loop 465. In variousembodiments, the loops may extend in any direction.

FIG. 15 and FIG. 16 illustrate two steps of a process to introducetension both longitudinally and laterally. As shown in FIG. 15 , a smallloop 575 is introduced into tensile element 571. A larger loop 565 isintroduced in tensile element 561. Loop 565 in tensile element 561 ispulled in the direction of the other tensile element, tensile element571, and is pulled across the surface of the outsole.

In a second step illustrated in FIG. 16 , loop 566 is pulledsufficiently to entrap the top 567 of loop 566 under tensile element 571at loop 576. Loop 576 then is eliminated to hold the top 567 of loop566. This arrangement introduces both longitudinal and lateral tensioninto this area of outsole 114.

FIG. 17 through FIG. 20 illustrate the method steps by whichground-engaging cleat members may be formed. As shown in FIG. 17 , mold300 is open, and knitted component 260, including first tensile element161, second tensile element 162, third tensile element 163, fourthtensile element 164, tensile element loops 166, and tensile elementleads 167, is placed between mold male part 302 and mold female part301, as shown by the direction of the arrow. FIG. 19 illustrates thatmale mold part 302 and female mold part 301 are moved together to pressknitted component 260 therebetween. As seen in FIG. 19 , the mold isclosed and the mold secures the edges of knitted component 260 to ensurethat knitted component 260 is stretched to form ground-engaging cleatmembers 115 when the mold is closed.

FIG. 20 illustrates that the mold parts have been separated, andone-piece outsole 112 has formed. In particular, the top surface of theoutsole 113 and ground-engaging cleat member 115 are visible as theknitted textile is removed in the direction of the arrow from theseparated mold. First tensile element 161, second tensile element 162,third tensile element 163, forth tensile element 164, tensile elementloops 166, and tensile element leads 167 also are illustrated.

In other embodiments, all protuberances may be formed essentiallysimultaneously by injection molding. Injection molding uses a fluidunder pressure to form protuberances in a surface, here the knittedcomponent. Injection molding may be used to inject materials such aselastomers and thermoplastic and thermosetting polymers. The knittedcomponent is held in place and the knitted component is stretched toform the protuberances. Typically, thermoplastic polymers are usedbecause such materials are well-suited for injection molding. Thermosetmaterials may react too quickly or not quickly enough while beinginjected. Further, thermoplastic polymers may be re-used and recycled,thus making such material an environmentally sensitive choice.

A knitted component is correctly oriented on the female mold part. Then,the mold is closed. The other part of the mold contains runners andother tubes for delivering the injected material through nozzles to themold cavity. Heated material is forced into the mold cavity to stretchthe knitted component and form the protuberances. The material cools andhardens to the configuration of the protuberances. The molds then areseparated and the molded knitted component is removed.

In some embodiments, the injected material remains in the protuberancesand provides rigidity. In some such embodiments, an additional featuresuch as a shank may be formed between the forefoot portion and the heelportion. The shank may provide additional rigidity to the outsole andthus to an article of footwear made with the sole system. In otherembodiments, the injected material may be removed from theprotuberances. In some such embodiments, the protuberances may be filledwith another rigid material, or may be filled with soft material toprovide a perception of cushioning.

FIG. 18 discloses another embodiment for forming ground-engaging cleatmember 115. Mold 350 includes female part 351 and injectors 352including nozzles 353. Each nozzle 353 corresponds with a cavity 354shaped to form a ground-engaging cleat member 115. Knitted component260, including first tensile element 161, second tensile element 162,third tensile element 163, fourth tensile element 164, tensile elementloops 166, and tensile element leads 167, is placed between theinjection nozzles, as shown by the arrow. Then, the mold parts arebrought together and a material is injected from nozzles 353 intocavities 354 to form ground-engaging cleat members 115.

The material injected may be left in a ground-engaging cleat member 115to provide additional support. Also, the individual pieces of injectedmaterial may be connected by a sprue or another manner. A mass ofinjected material also may be used to form a structure that willattenuate forces from the ground-engaging cleat member 115 reinforcementinto the wearer's foot. A skilled practitioner will be able, with theguidance provided herein, to select suitable materials for this purpose.

FIG. 21 illustrates a representation of a tensile element inlaid withinthe sole of a knitted component used to reduce differences in stress inan outsole. The top panel illustrates how formation of cleat 115 inoutsole portion 514 introduces stress into the knitted structure.Unstressed outsole portion 514 on the left then is moved into a press,such as that illustrated in FIG. 17 , as indicated by the movementarrows. When cleat 515 is formed by pressing, the area surrounding thecleat is subjected to essentially equal stress in all directions, thuscausing approximately equal stretching of the knitted component in thearea of the cleat. This approximately equivalent stretch is illustratedby expanded view 545 and arrows 540, which, by their relative size,illustrate approximately equal stress in all directions.

The center panel on FIG. 21 illustrates knitted component 554 havingtensile element 561 and tensile element 562 inlaid therein. Cleat 555 isformed by pressing down, displacing tensile element 561 and tensileelement 562 and introducing stress, as indicated by different arrows 556and 555. The magnitude of this stress introduced into knitted component554 is greater in the lateral direction (arrows 556) than in thelongitudinal direction (arrows 555). Knitted component 554 is stretchedclose to cleat 515, as illustrated in magnified view 559. The amount ofstress in this location can be compared to the lack of stress inmagnified view 558.

The bottom panel of FIG. 21 illustrates how the tensile elements may beused to restore a knitted component to typical stress or tension levels.Knitted component 554 having tensile element 561 and tensile element 562inlaid therein is pressed (movement arrows) to form cleat 515. To reducethe stress introduced by the pressing, loop 569 in tensile element 561is pulled to reduce the lateral stress. Loop 569 is pulled along thesurface of knitted component 554 and then secured under tensile element162, such as at 568, to retain the tension. Re-establishment of moretypical stress distribution is illustrated by equal-sized force arrows565 and by enlarged view of the knitted surface at 578 and 579. Enlargedview 578 illustrates a typical knit pattern away from cleat 515, as wasfound in enlarged view 558. Further, enlarged view 579 illustratesstress on knitted component 514 in the vicinity of cleat 515. The stresspattern at enlarged view essentially matches that at magnification 578away from cleat 515. This is because tensile element 162 has beenadjusted to relieve this stress.

FIG. 22 illustrates knitted component 280, another embodiment of aknitted component. In this embodiment, ground-engaging cleat members 118are knit into the one-piece knit outsole. Therefore, there is lessstress in the textile in the vicinity of the ground-engaging cleatmembers, and in the ground-engaging cleat members. In this embodiment,ground-engaging cleat members 118 are knitted into one-piece knitoutsole 112 as pockets or cavities extending from bottom surface 114 ofthe outsole. Each of ground-engaging cleat members 118 may be knittedfrom the same yarn as the remainder of the outsole 112; otherembodiments may form pockets using a different yarn. Such embodimentsmay require more than one feeder on knitting machine 200. First tensileelement 761, second tensile element 763, third tensile element 765,fourth tensile element 767, tensile element loops 762, and tensileelement leads 764 also are illustrated in FIG. 22 as adjacent to cleatmembers 118. Tensile element loops 762 and tensile element leads 764illustrate the path the inlaid tensile element takes during the knittingin the knitting machine.

FIG. 23 through FIG. 25 illustrate assembly of an article of footwear1000. Article of footwear 100 incorporates both an upper and a solesystem in a unitary knit construction, whereas article of footwear 1000comprises an upper separate from the sole system. FIG. 23 illustratessole system 1100, including knitted component 111 forming a one-pieceknit outsole 112 having top surface 113 and ground-engaging cleatmembers 118. The bottom surface or side 114 of the outsole and theground-engaging portion 116 of selected ground-engaging cleat members118 also are indicated.

FIG. 24 illustrates assembly of article of footwear 1000 using solesystem 1100. Upper 1200 is brought into contact with sole system 1100and affixed to the top surface 113 thereof. Upper 1200 may be made fromany material, such as leather, plastic, woven materials, and the like.FIG. 25 illustrates an assembled article of footwear 1000. This articleof footwear 1000 includes a one-piece knit outsole 114.

Still other embodiments provide a method of making a sole system for anarticle of footwear. In accordance with the method, a one-piece knittedcomponent is knitted to include a knit outsole. A ground-engaging cleatmember is formed in the ground-facing side of the knit outsole byknitting. A surface of the ground-engaging cleat member may include aknitted surface that contacts the ground.

Embodiments including a foot-enclosing sole system may comprise areas inwhich different yarns are used. Different types of yarns may impartdifferent properties to different areas of the knitted component. Bycombining various types and combinations of stitches and yarns, eacharea of knitted component may have specific properties that enhance thecomfort, durability, and performance of the article of footwear.

In such embodiments, tensile elements also may extend into portions ofthe knitted component forming the upper and may be inlaid within theknitted component portions forming the upper. Such embodiments areillustrated in FIG. 5 , FIG. 6 , and FIG. 7 , for example. Although thetensile elements illustrated in these figures run longitudinally, it maybe possible to inlay a tensile element laterally within the knittedcomponent. In such embodiments, the tensile element may be routedthrough the insole to pass from one side of the outsole to another. Thisarrangement would allow a single tensile element to be inlaid from oneside (lateral or medial, for example) of the upper through the outsole.In some embodiments, the tensile element may be inlaid around the cleatmembers and extended, whether by inlay or onlay, to the upper. Such anarrangement would aid in alignment of parts and secure attachment ofparts for form an article of footwear.

Embodiments of a sole system typically may include areas of durableyarns and fusible yarns. Durable yarns and fusible yarns typically mayprovide the wear resistance users likely will prefer to have inground-engaging areas and areas of the sole system that are likely toexperience greater wear. For example, the outer surface of the solesystem comprises a knitted textile, but is likely to experience greaterwear because the surface faces the ground and is, at least in part,adjacent ground-engaging protuberances that certainly may beground-engaging. Further, fusible yarns may provide not only excellentwear resistance, but also support for the bottom of the foot. Strands offusible yarn may, when heated, fuse to form an impermeable mass. Fusibleyarns also may provide a highly water resistant surface that helps keepthe interior of the article of footwear free of water that otherwisewould enter the article of footwear from the outside.

Suitable materials also may be added anywhere on the outer surface wherewater resistance or another property or characteristic, such asrigidity, is sought. Such materials, typically in the form of a film,may be applied to the surface of the knitted component before the solesystem is formed. Application of a film to a knitted component also maybe accomplished after formation of components of the sole system.

For example, resistance of an article of footwear to incursion of water,particularly through the sole system, may be increased by affixing athin film or water-resistant material on the outside surface of theoutsole. The entirety of the outer sole surface may be covered with thinfilm, or only a portion or portions of the lower surface may be coveredwith film for wear resistance and water repellence.

Suitable thin film materials include polymers such as polyethylene andpolypropylene, which may retain flexibility when bonded to the outersurface of a knitted component. Such films may suitably be used onsurfaces of a knitted component that preferably retain theirflexibility, such as an upper of an article of footwear. The skilledpractitioner will be able to identify appropriate films.

In other embodiments, a thin film may be rigid or resistant to bendingbefore or upon application, typically with heat and pressing.Application with heat and pressing causes the film to adhere or beingadhered to the knitted component. Such rigid film may be formed ofplural thin layers or one or two thicker layers. Plural materials may bestacked to form a more rigid film. A thicker, single layer also may beused.

Embodiments of a foot-enclosing sole system may include areas of softeryarns, compliant yarns, durable yarns, and fusible yarns, for example.Softer and compliant yarns typically may be used where comfort is animportant feature, with durable yarns used in areas susceptible to wear.In particular, embodiments may have fusible yarns on the outsole, theprotruding ground-engaging projection, and on the ground-engagingsurface. Fusible yarns may be particularly durable and may serve thesame purposes ascribed to them above. Similarly, a thin film may be usedto the same advantage as set forth above.

Another suitable yarn may be a core and sheath-type bi-componentconstruction. Core and sheath construction is obtained having a sheathof material having one set of properties essentially concentric with andsurrounding a core of yarn material having another set of properties andcharacteristics. In embodiments, the sheath material is one type of yarnhaving a first set of properties and characteristics. Other bi-componentyarns, such as “islands in the sea” type, also may be suitable. Suchyarns typically may have fusible material on the outside, just as a coreand sheath fiber has fusible material as a sheath material. Stillanother technique may be to spray a solvent-based fusible compositiononto yarn. In such embodiments, the solvent may be water, thus makingthe composition environmentally sensitive.

In still further embodiments, a plurality of yarns may be used toprovide transition zones for areas of the knitted component. Forexample, whereas durable, rigid yarns may be preferred for surfaces ofthe knitted component that are ground-facing, such yarns may not bepreferred for an upper of an article of footwear. Rather, softer, morecompliant yarns may be preferred on the upper, but such yarns may wearout prematurely in areas of high abrasion or stress, such as in the areaof the heel, for example. For such high abrasion areas, if may bepreferable to have a durable yarn.

In some embodiments, a rigid layer may be applied to both the top sideof the outsole and the ground-facing side of the outsole. Suchembodiments provide a rigid outsole, yet retain the look, properties,and characteristics of a knitted textile formed from a knittedcomponent. Further, the rigid layer of material attached to the top sideof the outsole may be useful in forming a protruding ground-engagingmember.

Other embodiments may include a rubberized portion on the ground-facingsurface of the outsole. A rubberized portion may be formed on thesurface of the outsole by painting on a rubberized material, by adheringa rubberized material to the portion of the knitted component that formsthe ground-facing surface of the outsole, or in any suitable method.

In embodiments having a layer of material on the ground-facing surfaceof the outsole, the shape of the layer may be formed to reduce adhesionof mud and dirt to the bottom of the sole, and thus to the bottom of anarticle of footwear incorporating the sole system. Various geometricshapes may be formed in the covering layer, or added to theground-facing surface of the outsole, to minimize adhesion of mud anddirt.

While various embodiments of the invention have been described, thedescription is intended to be exemplary rather than limiting, and itwill be apparent to those of ordinary skill in the art that many moreembodiments and implementations are possible that are within the scopeof the embodiments. Accordingly, the embodiments are not to berestricted except in light of the attached claims and their equivalents.Also, various modifications and changes may be made within the scope ofthe attached claims. As used in the claims, “any of”, when identifyingthe previous claims, is intended to mean (i) any one claim or (ii) anycombination of two or more claims identified.

1-19. (canceled)
 20. A method of making a sole system for an article offootwear, the method comprising: molding a one-piece knit outsole havinga ground-facing side, a top side, and a first tensile element inlaidwithin the knit outsole to form a ground-engaging cleat member; theground-engaging cleat member protruding from the ground-facing side ofthe knit outsole.
 21. The method of claim 20, wherein the first tensileelement is inlaid longitudinally within the knit outsole in a directionextending from a heel region to a toe region.
 22. The method of claim21, wherein the first tensile element is located adjacent aground-engaging cleat member.
 23. The method of claim 20, wherein thefirst tensile element is inlaid in a coursewise direction extendinglongitudinally from a heel region to a toe region.
 24. The method ofclaim 20, further comprising a second tensile element inlaid within theknit outsole.
 25. The method of claim 24, wherein the first tensileelement and the second tensile element are each inlaid in a course-wisedirection, and wherein the ground-engaging cleat member is positionedbetween the first tensile element and the second tensile element.
 26. Amethod of making a sole system for an article of footwear, the methodcomprising: knitting a one-piece knitted component, the one-pieceknitted component comprising a knit outsole having a top side and aground-facing side; inlaying a first tensile element into the one-pieceknitted component during knitting; and knitting a ground-engaging cleatmember on the ground-facing side of the knit outsole.
 27. The method ofclaim 26, further comprising inlaying a second tensile element into theone-piece knitted component during knitting.
 28. The method of claim 27,wherein the second tensile element is located adjacent theground-engaging cleat member.
 29. The method of claim 27, wherein thefirst tensile element and the second tensile element are each inlaid ina course-wise direction, and wherein the ground-engaging cleat member ispositioned between the first tensile element and the second tensileelement.
 30. The method of claim 26, wherein the first tensile elementis inlaid longitudinally within the knit outsole in a directionextending from a heel region to a toe region.
 31. A sole system for anarticle of footwear, the sole system comprising: a knitted componentcomprising a knit outsole that includes a bottom side and a top sidethat is opposite to the bottom side; a cleat protruding from the bottomside of the knit outsole; a first tensile element that is inlaid alongat least one course of the knit outsole and having at least one exposedportion extending over a surface of the knit outsole; and a secondtensile element that is inlaid along at least one course of the knitoutsole and having at least one exposed portion extending over thesurface of the knit outsole, the at least one exposed portion of thefirst tensile element forming a loop that extends from the first tensileelement to the second tensile element and is secured to the at least oneexposed portion of the second tensile element.
 32. The sole system ofclaim 31, wherein the first tensile element and the second tensileelement are inlaid longitudinally within the knit outsole in a directionextending from a heel region to a toe region.
 33. The sole system ofclaim 31, wherein the first tensile element and the second tensileelement each have additional exposed portions.
 34. The sole system ofclaim 31, wherein the loop formed by the at least one exposed portion ofthe first tensile element is longer than the at least one exposedportion of the second tensile element to which the loop is secured. 35.The sole system of claim 31, wherein the first tensile element and thesecond tensile element are each inlaid in a coursewise direction. 36.The sole system of claim 31, wherein a portion of the loop of the firsttensile element is arranged underneath the exposed portion of the secondtensile element.
 37. The sole system of claim 31, wherein the cleat ispositioned between the first tensile element and the second tensileelement.
 38. The sole system of claim 31, wherein the loop of the firsttensile element is adjacent the cleat.
 39. An article of footwearcomprising an upper secured to the sole system of claim 31.